Martin XB-907 in flight. (U.S. Air Force 060511-F-1234S-002)
16 February 1932: First flight, Glenn L. Martin Co. Model 123, designated XB-907 by the U. S. Army Air Corps. It was a streamlined all-metal mid-wing monoplane with retractable landing gear. It had an internal bomb bay. The airplane was flown by a single pilot and had two gunners, all in open cockpits.
The Model 123 was a private venture, designed and built at a cost of more than $200,000.
On 26 February 1932, the Model 123 was flown from the Martin plant in Middle River, Maryland, to the Aberdeen Proving Grounds by a U.S. Army Air Corps crew.
The XB-907 was powered by two air-cooled, supercharged 1,823.129-cubic-inch-displacement (29.875 liter) Wright Cyclone SR-1820-E nine-cylinder radial engines, rated at 600 horsepower, each. The engines were covered by Townend rings to reduce drag and improve cooling.
Martin XB-907
The prototype was tested at Wright Field. The airplane reached a maximum speed of 197 miles per hour (317 kilometers per hour) at 6,000 feet (1,829 meters). Recommendations for modifications were made, and Martin upgraded the prototype to the XB-907A configuration (Martin Model 139), which was then designated XB-10 by the Air Corps, with the serial number 33-139.
Martin XB-907A, right profile. (U.S. Air Force)
Martin increased the XB-907A’s wingspan from 62 feet, 2 inches (18.948 meters) to 70 feet, 7 inches (21.514 meters). The engines were upgraded to Wright R-1820-19s, rated at 675 horsepower. Full NACA cowlings were installed.
The Army then ordered 48 production airplanes.
The XB-907 would be developed into the Martin B-10 bomber.
U.S. Army Air Corps Martin B-10B of the 28th Bombardment Squadron, Philippine Islands 28 November 1939. (U.S. Air force)
15 February 1961, 09:05 UTC: This Boeing 707-329 airliner, registration OO-SJB, under the command of Captain Ludovic Marie Antoine Lambrechts and Captain Jean Roy, was enroute from Idlewild Airport, New York (IDL) to Brussels-Zaventem Airport (BRU) as SABENA Flight SN548, when three miles (4.8 kilometers) short of the runway at an altitude of 900 feet (274 meters), it pulled up, retracted its landing gear and accelerated.
The airliner made three 360° circles, with the angle of bank steadily increasing to 90°. The 707’s wings then leveled, followed by an abrupt pitch up. OO-SJB spiraled into a nose-down dive and crashed into an open field 1.9 miles (3 kilometers) northeast of Brussels and all 61 passengers and 11 crew members and 1 person on the ground were killed, including the entire U.S. Figure Skating Association team, their families, coaches, judges and officials.
“FIGURE 3: SABENA, Boeing 707, OO-SJB, accident 2 km NE of threshold of runway 20 at Brussels National Airport, Belgium, 15 February 1961” —ICAO Circular 69-AN/61, Page 58Wreckage of SABENA Flight SN548, Brussels, Belgium, 15 February 1961.
The cause of the crash was never determined but is suspected to be a mechanical failure in the flight control system:
Probable Cause
Having carried out all possible reasonable investigations, the Commission concluded that the cause of the accident had to be looked for in the material failure of the flying controls.
However, while it was possible to advance certain hypotheses regarding the possible causes, they could not be considered entirely satisfactory. Only the material failure of two systems could lead to a complete explanation, but left the way open to an arbitrary choice because there was not sufficient evidence to corroborate it.
—ICAO Circular 69-AN/61, Page 55, Column 2
The Federal Aviation Administration’s comments were included in the accident report:
“Of the several hypotheses evolving from findings in the accident report, we believe the most plausible to be that concerned with a malfunction of the stabilizer adjusting mechanism permitting the stabilizer to run to the 10.5-degree nose-up position. If such a malfunction occurred and the split flaps and spoilers procedure (inboard spoilers and outboard flaps extended) not employed, the only means to prevent the aircraft from pitching up into a stall would be to apply full forward column and enter a turn in either direction.”
“It is apparent from the recorded impact positions that the split flaps and spoilers technique was not used. The wing flaps were found in the up position and had the inboard spoilers been extended both would have been up at impact and the speed brake handle would not have been in the neutral position as found.”
—ICAO Circular 69-AN/61, Page 56, Column 2
Societé Anonyme Belge d’Exploitation de la Navigation Aérienne (SABENA) was the national airline of Belgium. It was based at Brussels and operated from 1923 to 2001.
The United States Figure Skating Association team, boarding SABENA Flight SN548 at Idlewild Airport, New York, 14 February 1961. From left in front row are: Deane McMinn, Laurence Rochon Owen, Steffi Westerfeld and Rhode Lee Michelson. From left on the bottom: Douglas Ramsay, Gregory Kelley, Bradley Lord, Maribel Y. Owen, Dudley Richards, William Hickox, Ray Hadley Jr., Laurie Hickox, Larry Pierce, Ila Ray Hadley, Roger Campbell, Diane Sherbloom, Dona Lee Carrier, and Robert and Patricia Dineen. (U.S.F.S.A.)This February 13, 1961 edition of Sports Illustrated was found in the burned-out wreckage of SABENA SN548. U.S.F.S.A. figure skater Laurence Rochon Owen’s photograph is on the cover. The 16-year-old skater is second from the left in the team photograph, above.
SABENA Flight SN548 was a Boeing 707-329 Intercontinental, OO-SJB, Boeing serial number 17624. It made its first test flight 13 December 1959 at Renton, Washington, and was delivered to SABENA in January 1960. At the time of the accident, it had just 3,038 total flight hours (TTAF). The airplane had undergone a Type II overhaul just 37 hours before the crash. ¹
The Boeing 707 was a jet airliner which had been developed from the Model 367–80 prototype, the “Dash Eighty.” It was a four-engine jet transport with swept wings and tail surfaces. The leading edge of the wings were swept at a 35° angle. The airliner had a flight crew of four: pilot, co-pilot, navigator and flight engineer.
The 707-329 Intercontinental is 152 feet, 11 inches (46.611 meters) long with a wing span of 145 feet, 9 inches (44.425 meters). The top of the vertical fin stands 42 feet, 5 inches (12.928 meters) high. The wing is considerably different than on the original 707-120 series, with increased length, different flaps and spoilers, and the engines are mounted further outboard. The vertical fin is taller, the horizontal tail plane has increased span, and there is a ventral fin for improved longitudinal stability. The 707 pre-dated the ”wide-body” airliners, having a fuselage width of 12 feet, 4 inches (3.759 meters).
SABENA Boeing 707-329 OO-SJD, a sistership of the accident aircraft, at Nice Côte d’Azur Airport, France. (Alain Durand/Wikipedia)
The the 707-320 International-series had an operating empty weight of 142,600 pounds (64,682 kilograms). Its maximum take off weight (MTOW) was 312,000 pounds (141,521 kilograms). When OO-SJB departed New York, its total weight was 119,500 kilograms (263,452 pounds), well below MTOW. It carried 50,000 kilograms (110,231 pounds) of JP-1 fuel.
OO-SJB was powered by four Pratt & Whitney Turbo Wasp JT4A engines. These were two-spool, axial-flow turbojet engine with a 15-stage compressor (8 low-, 7 high-pressure stages) and 3-stage turbine (1 high- and 2 low-pressure stages). The –12 was rated at 14,900 pounds of thrust (66.279 kilonewtons), maximum continuous power, and 17,500 pounds of thrust (77.844 kilonewtons) at 9,355 r.p.m. (N₂) for takeoff. The engine was 12 feet, 0.1 inches (3.660 meters) long, 3 feet, 6.5 inches (1.080 meters) in diameter, and weighed 4,895 pounds (2,220 kilograms).
The 707-329 had a maximum operating speed (MMO) of 0.887 Mach above 25,000 feet (7,620 meters). At 24,900 feet (7,590 meters), its maximum indicated airspeed (VMO) was 378 knots (435 miles per hour/700 kilometers per hour). At MTOW, the 707-329 required 10,840 feet (3,304 meters) of runway for takeoff. It had a range of 4,298 miles (6,917 kilometers).
The Boeing 707 was in production from 1958 to 1979. 1,010 were built.
The cover of the 13 February 1961 edition of Sports Illustrated. (SI)
According to the accident investigation report, following this overhaul, which took place from 11 January to 9 February 1961,
1) The pilot noted that during the first test flight on 9 February 1962 the trim button had to be pushed harder than normal. A second test flight was made to confirm the fault, after which the pilot noted “abnormal response of the stabilizer particularly after trimming nose down; slight nose up impulses give no result.”
2) The second incident was observed during the same flight. The pilot noted: “At the beginning of the flight there was a strong tendency of the aircraft to roll to the right. In level flight, the two left wing spoilers are 1 inch out.
“After descent, speed brakes out, at the moment of their retraction there was a marked roll to the right – it did not recur afterwards.
“At the end of the flight, the tendency to roll to the right was considerably diminished.”
—ICAO Circular 69-AN/61, Page 44, Column 2
In response to the stabilzer trim concern, maintenance replaced the stabilizer trim motor. It functioned normally during ground tests. As to the roll issue, an inspection following the flight did not reveal anything abnormal.
Douglas XC-112A 45-873 (W. T. Larkins Collection/Wikipedia)
15 February 1946: First flight of Douglas XC-112A (s/n 36326) 45-873.
In 1944, the U.S. Army Air Corps had requested a faster, higher-flying variant of the Douglas C-54E Skymaster, with a pressurized cabin. Douglas Aircraft Company developed the XC-112A in response. It was completed 11 February 1946 and made its first flight 4 days later. With the end of World War II, military requirements were scaled back and no orders for the type were placed.
Douglas saw a need for a new post-war civil airliner to compete with the Lockheed L-049 Constellation. Based on the XC-112A, the prototype Douglas DC-6 was built and made its first flight four months later, 29 June 1946.
Prototype Douglas DC-6 civil transport. (Century of Flight)
The Air Force ordered the twenty-sixth production Douglas DC-6 as a presidential transport, designated VC-118, The Independence. Beginning in 1951, the Air Force ordered a variant of the DC-6A as a the C-118A Liftmaster military transport and MC-118A medical transport. The U.S. Navy ordered it as the R6D-1.
The Douglas DC-6 was flown by a pilot, co-pilot, flight engineer and a navigator on longer flights. It was designed to carry between 48 and 68 passengers, depending on variant.
The DC-6 was 100 feet, 7 inches (30.658 meters) long with a wingspan of 117 feet, 6 inches (35.814 meters) and overall height of 28 feet, 5 inches (8.612 meters). The aircraft had an empty weight of 55,567 pounds (25,205 kilograms) and maximum takeoff weight of 97,200 pounds (44,090 kilograms).
The initial production DC-6 was powered by four 2,804.4-cubic-inch-displacement (45.956 liter), air-cooled, supercharged Pratt & Whitney Double Wasp CA15 two-row, 18 cylinder radial engines with a compression ratio of 6.75:1. The CA15 had a Normal Power rating of 1,800 h.p. at 2,600 r.p.m. at 6,000 feet (1,829 meters), 1,600 horsepower at 16,000 feet (4,877 meters), and 2,400 h.p. at 2,800 r.p.m with water injection for take off. The engines drove three-bladed Hamilton Standard Hydromatic 43E60 constant-speed propellers with a 15 foot, 2 inch (4.623 meter) diameter through a 0.450:1 gear reduction. The Double Wasp CA15 was 6 feet, 4.39 inches (1.940 meters) long, 4 feet, 4.80 inches (1.341 meters) in diameter, and weighed 2,330 pounds (1,057 kilograms).
The Douglas DC-6 had a cruise speed of 311 miles per hour (501 kilometers per hour) and range of 4,584 miles (7,377 kilometers).
XC-112A 45-873 was redesignated YC-112A and was retained by the Air Force before being transferred to the Civil Aeronautics Administration at Oklahoma City, where it was used as a ground trainer. 36326 was sold at auction as surplus equipment, and was purchased by Conner Airlines, Inc. Miami, Florida and received its first civil registration, N6166G, 1 August 1956. The YC-112A was certified in the transport category, 20 August 1956.
Conner Airlines sold 36326 to Compañia Ecuatoriana de Aviación (CEA), an Ecuadorian airline. Registered HC-ADJ, Ecuatoriana operated 36326 for several years.
It was next re-registered N6166G, 1 August 1962, owned by ASA International. A few months later, 1 May 1963, 36326 was registered to Trabajeros Aereos del Sahara SA (TASSA) a Spanish charter company specializing in the support of oil drilling operations in the Sahara, registered EC-AUC.
The XC-112A was operated as EC-AUC by TASSA Air Charter, seen here at London Gatwick, 29 August 1964. (RuthAS)
In 1965, with a private owner, 36326 was once again re-registered N6166G. Just two weeks after that, 1 June 1965, 36326 was registered to TransAir Canada as CF-TAX.
A TransAir DC-6
Two years later, 13 June 1967, Mercer Airlines bought 36326. This time the airplane was registered N901MA. Mercer was a charter company which also operated a Douglas C-47 and Douglas DC-4.
N901MA at Hollywood-Burbank Airport (Bureau d’Archives des Accidents d’Avion)
A Las Vegas, Nevada, hotel chartered Mercer Airlines to fly a group of passengers from Ontario International Airport (ONT), Ontario, California, to McCarran International Airport (LAS). On 8 February 1976, 36326, operating as Mercer Flight 901, was preparing to fly from Hollywood-Burbank Airport (BUR) where it was based, to ONT. The airliner had a flight crew of three: Captain James R. Seccombe, First Officer Jack R. Finger, Flight Engineer Arthur M. Bankers. There were two flight attendants in the passenger cabin, along with another Mercer employee.
Weather at BUR was reported as 1,000 feet (305 meters) scattered, 7,000 feet (2,134 meters) overcast, with visibility 4 miles (6.4 kilometers) in light rain and fog. The air temperature was 56 °F. (13.3 °C.), the wind was 180° at 4 knots (2 meters per second).
At 10:35 a.m. PST (18:35 UTC), Flight 901 was cleared for a rolling takeoff on Burbank’s Runway 15. While on takeoff roll, Flight Engineer Bankers observed a warning light for engine #3 (inboard, starboard wing). He called out a warning to the Captain, however, the takeoff continued.
Immediately after takeoff, a propeller blade on #3 failed. The intense vibration from the unbalanced propeller tore the #3 engine off of the airplane’s wing, and it fell on to the runway below.
The thrown blade passed through the lower fuselage, cut through hydraulic and pneumatic lines and electrical cables and then struck the #2 engine (inboard, port wing), further damaging the airplane’s electrical components and putting a large hole in that engine’s forward accessory drive case. The engine rapidly lost lubricating oil.
Flight 901 declared an emergency and requested to land on Runway 07, which was approved by the Burbank control tower, though they were informed that debris from the engine was on the runway at the intersection of 15/33 and 07/25. The airplane circled to the right to line up for Runway 07.
Just prior to touchdown, warning lights indicated that the propeller on the #2 engine had reversed. (In fact, it had not.) Captain Seccombe announced that they would only reverse #1 and #4 (the outboard engines, port and starboard wings) to slow 36326 after landing, and the airplane touched down very close to the approach end of the runway.
Because of the damage to the airplane’s systems, the outboard propellers would not reverse to slow the airplane and the service and emergency brakes also had failed. N901MA was in danger of running off the east end of the 6,055 foot (1,846 meters) runway, across the busy Hollywood Way and on into the city beyond.
The flight crew applied full power on the remaining three engines and again took off. The landing gear would not retract. The electrical systems failed. The #2 engine lost oil pressure and began to slow.
The DC-6 circled to the right again and headed toward Van Nuys Airport (VNY), 6.9 miles (11.1 kilometers) west of Hollywood-Burbank Airport. They informed Burbank tower that they would be landing on Van Nuys Runway 34L which was 8,000 feet (2,438 meters) long. Because of the emergency, the crew remained on Burbank’s radio frequency. The #2 engine then stopped but the propeller could not be feathered.
Hollywood-Burbank Airport (BUR) is at the right edge of this image, and Van Nuys Airport is at the left. Woodley Lakes Golf Course is just south of VNY. (Google Earth image)
Van Nuys weather was reported as 600 feet (183 meters) scattered, 10,000 feet (3,048 meters) overcast, with visibility 10 miles (16.1 kilometers) in light rain, temperature 55 °F. (12.8 °C.). The airliner was flying in and out of the clouds and the crew was on instruments. [1045: “Special, 1,200 scattered, 10,000 feet overcast, visibility—10 miles, rainshowers, wind—130° at 4 kn, altimeter setting—29.93 in.”]
Because of the drag of the unfeathered engine #2 propeller and the extended landing gear, the Flight 901 was unable to maintain altitude with the two remaining engines. The airplane was not able to reach the runway at VNY.
A forced landing was made on a golf course just south of the airport. The airplane touched down about 1 mile south of the threshold of Runway 34L on the main landing gear and bounced three times. At 10:44:55, the nose then struck the foundation of a partially constructed building, crushing the cockpit. All three flight crew members were killed by the impact.
Douglas YC-112A serial number 36326, N901MA, shortly after crash landing at Woodley Golf Course, Van Nuys, California, 8 February 1976. (Bureau d’Archives des Accidents d’Avions)
Both flight attendants were trapped under their damaged seats but were able to free themselves. They and the passenger were able to escape from the wreck with minor injuries.
Los Angeles City Fire Department firefighters attempted to rescue the crew by cutting into the fuselage. Even though the area around the airplane had been covered with fire-retardant foam, at about 20 minutes after the crash, sparks from the power saw ignited gasoline fumes. Fire erupted around the airplane. Ten firefighters were burned, three severely. N901MA was destroyed.
“Feb. 8, 1976: Firemen scatter after saw ignites gas fumes at crash site of DC-6 in Van Nuys. Three trapped crew members of Mercer Enterprises DC-6 charter plane died. Ten firemen were injured.” (Boris Yaro/Los Angeles Times)
At the time of the accident, YC-112A 36326 was just three days short of the 30th anniversary of its completion at Douglas. It had flown a total of 10,280.4 hours. It was powered by three Pratt & Whitney R-2800-83 AMS, and one R-2800-CA18 Double Wasp engines. All four engines drove three-bladed Curtiss-Wright Type C632-S constant-speed propellers. The failed propeller had been overhauled then installed on N901MA 85 hours prior to the 8 February flight.
The National Transportation Safety Board investigated the accident. It was found that a fatigue fracture in the leading edge of the propeller blade had caused the failure. Though the propeller had recently been overhauled, it was discovered that the most recent procedures had not been followed. This required that the rubber deicing boots be stripped so that a magnetic inspection could be made of the blade’s entire surface. Because this had not been done, the crack in the hollow steel blade was not found.
Boeing YAL-1A, 00-0001, Airborne Laser Test Aircraft, departing Edwards AFB, 14 February 2012. (U.S. Air Force)Terrier Black Brant IX two-stage sounding rocket. (NASA)
14 February 2012: Boeing YAL-1A Airborne Laser Test Bed, serial number 00-0001, departed Edwards AFB for the last time as it headed for The Boneyard at Davis-Monthan Air Force Base, Tucson, Arizona.
The Boeing YAL-1A was built from a 747-4G4F, a converted 747-400F freighter, serial number 30201, formerly operated by Japan Air Lines and registered JA402J. It carried two solid state lasers and a megawatt-class oxygen iodine directed energy weapon system (COIL).
On 3 February 2010, it destroyed a Terrier Black Brant two-stage sounding rocket in the boost phase as it was launched from San Nicolas Island, off the coast of Southern California.
Boeing YAL-1A Airborne Laser Test Aircraft, 00-0001, in flight. The laser aiming turret is directed toward the photo aircraft. (U.S. Air Force)
The 747-400 was a major development of the 747 series. It had many structural and electronics improvements over the earlier models, which had debuted 18 years earlier. New systems, such as a “glass cockpit”, flight management computers, and new engines allowed it to be flown with a crew of just two pilots, and the position of Flight Engineer became unnecessary.
The most visible features of the –400 are its longer upper deck and the six-foot tall “winglets” at the end of each wing, which improve aerodynamic efficiency be limiting the formation of wing-tip vortices.
Japan Air Lines’ Boeing 747-400F, JA402J. (Konstantin von Wedelstaedt/Wikimedia)
The Boeing 747-400F is the freighter version of the 747-400 airliner. It has a shorter upper deck, no passenger windows and the nose can swing upward to allow cargo pallets or containers to be loaded. It is 231 feet, 10 inches (70.663 meters) long with a wingspan of 211 feet, 5 inches (64.440 meters) and overall height of 63 feet, 8 inches (19.406 meters). Empty weight is 394,100 pounds (178,761 kilograms). Maximum takeoff weight (MTOW) is 875,000 pounds (396,893 kilograms).
Boeing YAL-1A Airborne Laser Test Aircraft, 00-0001. (U.S. Missile Defense Agency)
The YAL-1A was powered by four General Electric CF6-80C2B5F turbofan engines, producing 62,100 pounds of thrust (276.235 kilonewtons), each. The CF6-80C2B5F is a two-spool, high-bypass-ratio turbofan engine. It has a single-stage fan section, 18-stage compressor (4 low- and 14 high-pressure stages) and 7-stage turbine section (2 high- and 5 low-pressure stages). The fan diameter is 7 feet, 9.0 inches (2.362 meters). The engine is 13 feet, 4.9 inches (4.087 meters) long with a maximum diameter of 8 feet, 10.0 inches (2.692 meters). It weighs 9,760 pounds (4,427 kilograms).
It had a cruise speed of 0.84 Mach (555 miles per hour, 893 kilometers per hour) at 35,000 feet (10,668 meters) and maximum speed of 0.92 Mach (608 miles per hour, 978 kilometers hour). Maximum range at maximum payload weight is 7,260 nautical miles (13,446 kilometers).
Boeing YAL-1A in storage at Davis-Monthan Air Force Base, 27 August 2014. The airframe was disassembled and finally broken up 25 September 2014. (Soracat)
McDonnell Douglas F-15E-47-MC Strike Eagle 89-0487 at Bagram Airfield, Afghanistan. (Photo by Airman 1st Class Ericka Engblom, U.S.Air Force.)
14 February 1991: An unusual incident occurred during Desert Storm, when Captains Tim Bennett and Dan Bakke, United States Air Force, flying the airplane in the above photograph, McDonnell Douglas F-15E-47-MC Strike Eagle, 89-0487, used a 2,000-pound (907.2 kilogram) GBU-10 Paveway II laser-guided bomb to “shoot down” an Iraqi Mil Mi-24 Hind attack helicopter. This airplane is still in service with the Air Force, and on 17 May 2024 logged its 15,000th flight hour.
Captain Bennett (Pilot) and Captain Bakke (Weapon Systems Officer) were leading a two-ship flight on a anti-Scud missile patrol, waiting for a target to be assigned by their Boeing E-3 AWACS controller. 89-0487 was armed with four laser-guided GBU-10 bombs and four AIM-9 Sidewinder heat-seeking air-to-air missiles. Their wingman was carrying twelve Mk. 82 500-pound (227 kilogram) bombs.
The AWACS controller called Bennett’s flight and told them that a Special Forces team on the ground searching for Scud launching sites had been located by Iraqi forces and was in need of help. They headed in from 50 miles (80.5 kilometers) away, descending though 12,000 feet (3,658 meters) of clouds as the went. They came out of the clouds at 2,500 feet (762 meters), 15–20 miles (24– 32 kilometers) from the Special Forces team.
With the Strike Eagle’s infrared targeting pod, they picked up five helicopters and identified them as enemy Mi-24s. It appeared that the helicopters were trying to drive the U.S. soldiers into a waiting Iraqi blocking force.
Iraqi Army Aviation Mil Mi-24 Hind (helis.com)
Their Strike Eagle was inbound at 600 knots (1,111 kilometers per hour) and both the FLIR (infrared) targeting pod and search radar were locked on to the Iraqi helicopters. Dan Bakke aimed the laser targeting designator at the lead helicopter preparing to drop a GBU-10 while Tim Bennett was getting a Sidewinder missile ready to fire. At four miles (6.44 kilometers) they released the GBU-10.
Mission count for the 10,000+ flight hours of F-15E 89-0487. The green star indicates the Iraqi Mi-24 helicopter destroyed 14 February 1991. (U.S. Air Force)
At this time, the enemy helicopter, which had been either on the ground or in a hover, began to accelerate and climb. The Eagle’s radar showed the helicopter’s ground speed at 100 knots. Bakke struggled to keep the laser designator on the fast-moving target. Bennett was about to fire the Sidewinder at the helicopter when the 2,000-pound (907.2 kilogram) bomb hit and detonated. The helicopter ceased to exist. The other four helicopters scattered.
Soon after, additional fighter bombers arrived to defend the U.S. Special Forces team. They were later extracted and were able to confirm the Strike Eagle’s kill.
A Royal Australian Air Force fighter pilot checks a GBU-10 Paveway II 2,000-pound (907.2 kilogram) laser-guided bomb on an F-18 Hornet. This is the same type of bomb used by Captains Bennett and Bakke to destroy an Iraqi Mil Mi-24 Hind attack helicopter. (RAAF)
The Strike Eagle was begun as a private venture by McDonnell Douglas. Designed to be operated by a pilot and a weapon system officer (WSO), the airplane can carry bombs, missiles and guns for a ground attack role, while maintaining its capability as an air superiority fighter. It’s airframe was a strengthened and its service life doubled to 16,000 flight hours. The Strike Eagle became an Air Force project in March 1981, and went into production as the F-15E. The first production model, 86-0183, made its first flight 11 December 1986.
The prototype McDonnell Douglas F-15E Strike Eagle (modified from F-15B-4-MC 71-0291) is parked on the ramp at the McDonnell Douglas facility at St. Louis. (U.S. Air Force)
The McDonnell Douglas F-15E Strike Eagle is a two-place twin-engine multi-role fighter. It is 63 feet, 9 inches (19.431 meters) long with a wingspan of 42 feet, 9¾ inches (13.049 meters) and height of 18 feet, 5½ inches (5.626 meters). It weighs 31,700 pounds (14,379 kilograms) empty and has a maximum takeoff weight of 81,000 pounds (36,741 kilograms).
The F-15E is powered by two Pratt and Whitney F100-PW-229 turbofan engines which produce 17,800 pounds of thrust (79.178 kilonewtons) each, or 29,100 pounds (129.443 kilonewtons) with afterburner.
The Strike Eagle has a maximum speed of Mach 2.54 (1,676 miles per hour, (2,697 kilometers per hour) at 40,000 feet (12,192 meters) and is capable of sustained speed at Mach 2.3 (1,520 miles per hour, 2,446 kilometers per hour). Its service ceiling is 60,000 feet (18,288 meters). The fighter-bomber has a combat radius of 790 miles (1,271 kilometers) and a maximum ferry range of 2,765 miles (4,450 kilometers).
Though optimized as a fighter-bomber, the F-15E Strike Eagle retains an air-to-air combat capability. The F-15E is armed with one 20mm M61A1 Vulcan 6-barrel rotary cannon with 512 rounds of ammunition, and can carry four AIM-9M Sidewinder heat-seeking missiles and four AIM-7M Sparrow radar-guided missiles, or a combination of Sidewinders, Sparrows and AIM-120 AMRAAM long range missiles. It can carry a maximum load of 24,500 pounds (11,113 kilograms) of bombs and missiles for ground attack.
A McDonnell Douglas F-15E Strike Eagle over Iraq during Operation Northern Watch, 1999. (U.S. Air Force)
The Mil Mi-24 (NATO reporting name “Hind”) is a large, heavily-armed attack helicopter that can also carry up to eight troops. It is flown by a pilot and a gunner.
It is 57 feet, 4 inches (17.475 meters) long and the five-bladed main rotor has a diameter of 56 feet, 7 inches (17.247 meters). The helicopter has an overall height of 21 feet, 3 inches (6.477 meters). The empty weight is 18,740 pounds (8,378 kilograms) and maximum takeoff weight is 26,500 pounds (12,020 kilograms).
The helicopter is powered by two Isotov TV3-117 turboshaft engines which produce 2,200 horsepower, each. The Mil-24 has a maximum speed of 208 miles per hour (335 kilometers per hour) and a range of 280 miles (451 kilometers). Its service ceiling is 14,750 feet (4,496 meters).
The helicopter is armed with a 12.7 mm Yakushev-Borzov Yak-B four-barreled Gatling gun with 1,470 rounds of ammunition; a twin-barrel GSh-30K 30 mm autocannon with 750 rounds; a twin-barrel GSh-23L 23 mm autocannon with 450 rounds. The Mi-24 can also carry a wide range of bombs, rockets and missiles.
The Mil Mi-24 first flew in 1969 and is still in production. More than 2,300 have been built and they have served the militaries of forty countries.
A Russian-built Mil Mi-24P Hind-F at the U.S. Army Test and Evaluation Center, Threat Support Activity, NAS Fallon, Nevada. (United States Air Force)
